// Copyright (c) Advanced Micro Devices, Inc., or its affiliates.
// SPDX-License-Identifier: MIT

#pragma once

#include "ck_tile/host.hpp"
#include "fmha_bwd.hpp"
#include "utils.hpp"
#include "ck_tile/utility/json_dump.hpp"

#include <array>
#include <cstring>
#include <functional>
#include <numeric>
#include <ostream>
#include <string>
#include <tuple>
#include <utility>
#include <vector>

enum class bwd_result
{
    success,
    failure,
    invalid_args,
    no_instance,
};

// different threshold for different dtype
template <typename DataTypeConfig>
auto get_elimit(ck_tile::index_t /*hdim_q*/, ck_tile::index_t /*hdim_v*/)
{
    double rtol = 1e-2;
    double atol = 1e-2;
    return ck_tile::make_tuple(rtol, atol);
}

template <>
auto get_elimit<FmhaBwdFp32>(ck_tile::index_t /*hdim_q*/, ck_tile::index_t /*hdim_v*/)
{
    double rtol = 1e-4;
    double atol = 1e-4;
    return ck_tile::make_tuple(rtol, atol);
}

template <>
auto get_elimit<FmhaBwdBf16>(ck_tile::index_t hdim_q, ck_tile::index_t hdim_v)
{
    double rtol = 1e-2;
    double atol = 1e-2;
    if(hdim_q > 128 && hdim_v > 128) // 3.2 for RTZ/1.5 for RTN
    {
        rtol = 3.2e-2;
        atol = 3.2e-2;
    }
    return ck_tile::make_tuple(rtol, atol);
}

extern template float fmha_bwd<2>(fmha_bwd_traits, fmha_bwd_args, const ck_tile::stream_config&);

template <typename DataTypeConfig>
bwd_result fmha_bwd_run(mode_enum mode,
                        ck_tile::index_t batch,
                        ck_tile::index_t nhead,
                        ck_tile::index_t nhead_k,
                        std::vector<ck_tile::index_t> seqlen_qs,
                        std::vector<ck_tile::index_t> seqlen_ks,
                        std::vector<ck_tile::index_t> seqlen_qpads,
                        std::vector<ck_tile::index_t> seqlen_kpads,
                        ck_tile::index_t hdim_q,
                        ck_tile::index_t hdim_v,
                        bool i_perm,
                        bool o_perm,
                        float scale,
                        std::string bias_str,
                        bool use_dbias,
                        float p_drop,
                        uint64_t drop_seed,
                        uint64_t drop_offset,
                        bool drop_prefs,
                        std::string mask_str,
                        bool deterministic,
                        std::string init_method,
                        uint32_t seed,
                        int do_validation,
                        const ck_tile::stream_config& stream_config,
                        std::optional<std::string> json = std::nullopt)
{
    const std::string data_type = []() {
        if constexpr(std::is_same_v<DataTypeConfig, FmhaBwdFp32>)
            return "fp32";
        else if constexpr(std::is_same_v<DataTypeConfig, FmhaBwdFp16>)
            return "fp16";
        else if constexpr(std::is_same_v<DataTypeConfig, FmhaBwdBf16>)
            return "bf16";
        else
            static_assert(false);
    }();

    if(nhead_k < 0)
        nhead_k = nhead;
    if(nhead % nhead_k != 0)
    {
        std::cerr << "nhead:" << nhead << " must be multiple of nhead_k:" << nhead_k << std::endl;
        return bwd_result::invalid_args;
    }

    std::mt19937 random_engine(seed != 0 ? seed : std::random_device{}());
    auto next_seed = [&random_engine]() { return static_cast<unsigned int>(random_engine()); };

    if(hdim_v < 0)
        hdim_v = hdim_q;

    if(scale == .0f)
        scale = 1.0 / ck_tile::sqrt(static_cast<float>(hdim_q));

    bias_info bias = bias_info::decode(bias_str);

    if(use_dbias && bias.type != bias_enum::elementwise_bias)
    {
        std::cerr << "dbias only exists when bias type is elementwise" << std::endl;
        return bwd_result::invalid_args;
    }

    std::tie(seqlen_qs, seqlen_ks, seqlen_qpads, seqlen_kpads) = generate_missing_seqlens(
        mode, batch, seqlen_qs, seqlen_ks, seqlen_qpads, seqlen_kpads, 0, false, random_engine);

    bool use_qpadding =
        mode == mode_enum::group && (!seqlen_qpads.empty() && seqlen_qpads[0] != -1);
    bool use_kpadding =
        mode == mode_enum::group && (!seqlen_kpads.empty() && seqlen_kpads[0] != -1);

#if 0
    std::cout << "use_qpadding: " << use_qpadding << std::endl;
    std::cout << "use_kpadding: " << use_kpadding << std::endl;
    std::cout << "seqlen_qs: " << seqlen_qs << std::endl;
    std::cout << "seqlen_ks: " << seqlen_ks << std::endl;
    if (use_qpadding) {
        std::cout << "seqlen_qpads: " << seqlen_qpads << std::endl;
    }
    if (use_kpadding) {
        std::cout << "seqlen_kpads: " << seqlen_kpads << std::endl;
    }
#endif

    mask_info mask = mask_info::decode(mask_str, seqlen_qs[0], seqlen_ks[0]);

    if(p_drop < 0.0f || p_drop > 1.0f)
    {
        std::cerr << "The value of p_drop should be 0~1" << std::endl;
        return bwd_result::invalid_args;
    }
    float p_undrop = 1.0 - p_drop;
    uint8_t p_undrop_in_uint8_t =
        uint8_t(std::floor(p_undrop * std::numeric_limits<uint8_t>::max()));
    float rp_undrop = 1.0 / p_undrop;

    bool s_randval = false;
    if(p_drop > 0.0f && do_validation)
    {
        s_randval = true;
    }

    const auto seqstart_q_host =
        (use_qpadding ? to_seqstarts(seqlen_qpads) : to_seqstarts(seqlen_qs));
    const auto seqstart_k_host =
        (use_kpadding ? to_seqstarts(seqlen_kpads) : to_seqstarts(seqlen_ks));

    using TypeConfig = FmhaBwdTypeConfig<DataTypeConfig>;

    using QDataType             = typename TypeConfig::QDataType;
    using KDataType             = typename TypeConfig::KDataType;
    using VDataType             = typename TypeConfig::VDataType;
    using GemmDataType          = typename TypeConfig::GemmDataType;
    using BiasDataType          = typename TypeConfig::BiasDataType;
    using LSEDataType           = typename TypeConfig::LSEDataType;
    using AccDataType           = typename TypeConfig::AccDataType;
    using DDataType             = typename TypeConfig::DDataType;
    using RandValOutputDataType = typename TypeConfig::RandValOutputDataType;
    using ODataType             = typename TypeConfig::ODataType;
    using OGradDataType         = typename TypeConfig::OGradDataType;
    using QGradDataType         = typename TypeConfig::QGradDataType;
    using KGradDataType         = typename TypeConfig::KGradDataType;
    using VGradDataType         = typename TypeConfig::VGradDataType;
    using BiasGradDataType      = typename TypeConfig::BiasGradDataType;

    // accumulation numbers for performance evaluation
    std::size_t flop = 0, num_byte = 0;
    auto max_seqlen_q =
        std::numeric_limits<int32_t>::min(); // we will use max seqlen to decide grid size
    auto max_seqlen_k =
        std::numeric_limits<int32_t>::min(); // we will use max seqlen to decide grid size
    {
        for(ck_tile::index_t wb = 0; wb < batch; ++wb)
        {
            // When padding is enabled, use logical lengths for flop/bandwidth calculation
            const int32_t real_seqlen_q =
                use_qpadding ? seqlen_qs[wb] : (seqstart_q_host[wb + 1] - seqstart_q_host[wb]);
            const int32_t real_seqlen_k =
                use_kpadding ? seqlen_ks[wb] : (seqstart_k_host[wb + 1] - seqstart_k_host[wb]);

            if(max_seqlen_q < real_seqlen_q)
            {
                max_seqlen_q = real_seqlen_q;
            }

            if(max_seqlen_k < real_seqlen_k)
            {
                max_seqlen_k = real_seqlen_k;
            }

            flop += nhead * (static_cast<std::size_t>(3) * static_cast<std::size_t>(2) *
                                 real_seqlen_q * real_seqlen_k * hdim_q + // Q@K/dS^T@Q^T/dS@K^T
                             static_cast<std::size_t>(2) * static_cast<std::size_t>(2) *
                                 real_seqlen_q * real_seqlen_k * hdim_v); // dO@V/P^T@dO^T

            num_byte += nhead * (sizeof(QDataType) * real_seqlen_q * hdim_q +
                                 sizeof(KDataType) * real_seqlen_k * hdim_q +
                                 sizeof(VDataType) * real_seqlen_k * hdim_v +
                                 sizeof(ODataType) * real_seqlen_q * hdim_v +
                                 sizeof(OGradDataType) * real_seqlen_q * hdim_v +
                                 sizeof(QGradDataType) * real_seqlen_q * hdim_q +
                                 sizeof(KGradDataType) * real_seqlen_k * hdim_q +
                                 sizeof(VGradDataType) * real_seqlen_k * hdim_v +
                                 sizeof(LSEDataType) * real_seqlen_q);
        }
    }

    auto get_lengths = [&](bool permute,
                           ck_tile::index_t b /*batch*/,
                           ck_tile::index_t h /*nhead*/,
                           ck_tile::index_t s /*seqlen*/,
                           ck_tile::index_t d /*hdim*/) {
        if(permute)
            return std::array<ck_tile::index_t, 4>{b, h, s, d};
        else
            return std::array<ck_tile::index_t, 4>{b, s, h, d};
    };

    // host memory for storing all the tensor elements
    const ck_tile::index_t shape_batch = (mode == mode_enum::batch ? batch : 1);
    const ck_tile::index_t shape_seqlen_q =
        (mode == mode_enum::batch ? seqlen_qs[0] : seqstart_q_host.back());
    const ck_tile::index_t shape_seqlen_k =
        (mode == mode_enum::batch ? seqlen_ks[0] : seqstart_k_host.back());
    // Keep it equal to or smaller than minimal bn0 of all tiles in fmha_bwd.py
    // TODO: add API for requesting kN0/nsplits/workspace_size? It is not safe to rely on internal
    // implementation details in client code.
    const ck_tile::index_t kN0 = 16;
    const ck_tile::index_t nsplits =
        deterministic ? ck_tile::integer_divide_ceil(max_seqlen_k, kN0) : 1;

    ck_tile::HostTensor<QDataType> q_host(
        get_lengths(i_perm, shape_batch, nhead, shape_seqlen_q, hdim_q));
    ck_tile::HostTensor<KDataType> k_host(
        get_lengths(i_perm, shape_batch, nhead_k, shape_seqlen_k, hdim_q));
    ck_tile::HostTensor<VDataType> v_host(
        get_lengths(i_perm, shape_batch, nhead_k, shape_seqlen_k, hdim_v));
    ck_tile::HostTensor<BiasDataType> bias_host(
        bias.type == bias_enum::elementwise_bias
            ? get_lengths(i_perm, 1, 1, shape_seqlen_q, max_seqlen_k)
            : std::array<ck_tile::index_t, 4>{1, 1, 1, 1} /* dummy shape for simplifying code */);
    ck_tile::HostTensor<AccDataType> alibi_slope_host(
        bias.type == bias_enum::alibi
            ? (bias.rank_info == 0 ? std::array<ck_tile::index_t, 2>{1, nhead}
                                   : std::array<ck_tile::index_t, 2>{batch, nhead})
            : std::array<ck_tile::index_t, 2>{1, 1});
    ck_tile::HostTensor<ODataType> o_host(
        get_lengths(o_perm, shape_batch, nhead, shape_seqlen_q, hdim_v));
    ck_tile::HostTensor<LSEDataType> lse_host(
        std::array<ck_tile::index_t, 3>{shape_batch, nhead, shape_seqlen_q});
    ck_tile::HostTensor<DDataType> d_host(
        std::array<ck_tile::index_t, 3>{shape_batch, nhead, shape_seqlen_q});
    ck_tile::HostTensor<RandValOutputDataType> randval_host(
        p_drop > 0 ? get_lengths(true, shape_batch, nhead, shape_seqlen_q, max_seqlen_k)
                   : std::array<ck_tile::index_t, 4>{1, 1, 1, 1});
    ck_tile::HostTensor<QGradDataType> dq_host(
        get_lengths(i_perm, shape_batch, nhead, shape_seqlen_q, hdim_q));
    ck_tile::HostTensor<KGradDataType> dk_host(
        get_lengths(i_perm, shape_batch, nhead, shape_seqlen_k, hdim_q));
    ck_tile::HostTensor<VGradDataType> dv_host(
        get_lengths(i_perm, shape_batch, nhead, shape_seqlen_k, hdim_v));
    ck_tile::HostTensor<OGradDataType> do_host(
        get_lengths(o_perm, shape_batch, nhead, shape_seqlen_q, hdim_v));
    ck_tile::HostTensor<BiasGradDataType> dbias_host(
        use_dbias
            ? get_lengths(i_perm, shape_batch, nhead, shape_seqlen_q, max_seqlen_k)
            : std::array<ck_tile::index_t, 4>{1, 1, 1, 1} /* dummy shape for simplifying code */);
    ck_tile::HostTensor<AccDataType> dq_acc_host(
        i_perm
            ? std::array<ck_tile::index_t, 5>{nsplits, shape_batch, nhead, shape_seqlen_q, hdim_q}
            : std::array<ck_tile::index_t, 5>{nsplits, shape_batch, shape_seqlen_q, nhead, hdim_q});

    if(init_method == "ui" || init_method == "0")
    {
        ck_tile::FillUniformDistributionIntegerValue<QDataType>{-2.f, 2.f, next_seed()}(q_host);
        ck_tile::FillUniformDistributionIntegerValue<KDataType>{-2.f, 2.f, next_seed()}(k_host);
        ck_tile::FillUniformDistributionIntegerValue<VDataType>{-2.f, 2.f, next_seed()}(v_host);
        ck_tile::FillUniformDistributionIntegerValue<BiasDataType>{-2.f, 2.f, next_seed()}(
            bias_host);
        ck_tile::FillUniformDistributionIntegerValue<OGradDataType>{-2.f, 2.f, next_seed()}(
            do_host);
    }
    else if(init_method == "uf" || init_method == "1")
    {
        ck_tile::FillUniformDistribution<QDataType>{0.f, 1.f, next_seed()}(q_host);
        ck_tile::FillUniformDistribution<KDataType>{0.f, 1.f, next_seed()}(k_host);
        ck_tile::FillUniformDistribution<VDataType>{0.f, 1.f, next_seed()}(v_host);
        ck_tile::FillUniformDistribution<BiasDataType>{0.f, 1.f, next_seed()}(bias_host);
        ck_tile::FillUniformDistribution<OGradDataType>{0.f, 1.f, next_seed()}(do_host);
    }
    else if(init_method == "tf" || init_method == "2")
    {
        ck_tile::FillTrigValue<QDataType>{}(q_host);
        ck_tile::FillTrigValue<KDataType>{}(k_host);
        ck_tile::FillTrigValue<VDataType>{}(v_host);
        ck_tile::FillTrigValue<BiasDataType>{}(bias_host);
        ck_tile::FillTrigValue<OGradDataType>{}(do_host);
    }
    else
    {
        std::cerr << "Unknown value for init argument: " << init_method << std::endl;
        return bwd_result::invalid_args;
    }

    if(bias.type == bias_enum::alibi)
    {
        auto slopes = ck_tile::get_alibi_slopes<AccDataType>(nhead);
        assert(slopes.size() == static_cast<decltype(slopes.size())>(nhead));
        if(bias.rank_info == 0)
        {
            // alibi in 1*h
            std::copy(slopes.begin(), slopes.end(), alibi_slope_host.begin());
        }
        else
        {
            // alibi in b*h
            for(auto i_b = 0; i_b < batch; i_b++)
            {
                std::copy(slopes.begin(), slopes.end(), alibi_slope_host.begin() + i_b * nhead);
            }
        }
    }

    ck_tile::DeviceMem q_buf(q_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem k_buf(k_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem v_buf(v_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem bias_buf(bias_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem o_buf(o_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem lse_buf(lse_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem d_buf(d_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem randval_buf(randval_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem dq_buf(dq_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem dk_buf(dk_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem dv_buf(dv_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem do_buf(do_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem dbias_buf(dbias_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem seqstart_q(seqstart_q_host.size() * sizeof(int32_t));
    ck_tile::DeviceMem seqlen_q_dev(mode == mode_enum::batch ? 0
                                                             : seqlen_qs.size() * sizeof(int32_t));
    ck_tile::DeviceMem seqlen_k_dev(mode == mode_enum::batch ? 0
                                                             : seqlen_ks.size() * sizeof(int32_t));
    ck_tile::DeviceMem seqstart_k(seqstart_k_host.size() * sizeof(int32_t));
    ck_tile::DeviceMem drop_seed_buf(drop_prefs ? sizeof(uint64_t) : 0);
    ck_tile::DeviceMem drop_offset_buf(drop_prefs ? sizeof(uint64_t) : 0);
    ck_tile::DeviceMem alibi_slope_buf(alibi_slope_host.get_element_space_size_in_bytes());
    ck_tile::DeviceMem dq_acc_buf(dq_acc_host.get_element_space_size_in_bytes());

    q_buf.ToDevice(q_host.data());
    k_buf.ToDevice(k_host.data());
    v_buf.ToDevice(v_host.data());
    bias_buf.ToDevice(bias_host.data());
    do_buf.ToDevice(do_host.data());
    seqstart_q.ToDevice(seqstart_q_host.data());
    seqstart_k.ToDevice(seqstart_k_host.data());
    if(mode == mode_enum::group)
    {
        std::vector<int32_t> seqlen_q_host(seqlen_qs.begin(), seqlen_qs.end());
        seqlen_q_dev.ToDevice(seqlen_q_host.data());
        std::vector<int32_t> seqlen_k_host(seqlen_ks.begin(), seqlen_ks.end());
        seqlen_k_dev.ToDevice(seqlen_k_host.data());
    }
    drop_seed_buf.ToDevice(drop_prefs ? &drop_seed : nullptr);
    drop_offset_buf.ToDevice(drop_prefs ? &drop_offset : nullptr);
    alibi_slope_buf.ToDevice(alibi_slope_host.data());

    // clang-format off
    auto layout_str = [&](bool permute){
        if (permute) return std::string("bhsd");
        else return std::string("bshd");
    };
    auto io_layout = [&](bool iperm_, bool operm_) {
        if (iperm_ == operm_) return layout_str(iperm_);
        else return layout_str(iperm_) + std::string("-") + layout_str(operm_);
    };
    // clang-format on

    const std::size_t workspace_size_in_megabytes =
        ck_tile::integer_divide_ceil(dq_acc_host.get_element_space_size_in_bytes(), 1024 * 1024);

    std::cout << "[" << data_type << "|" << mode << "|" << io_layout(i_perm, o_perm)
              << "] b:" << batch << ", h:" << nhead << "/" << nhead_k << ", s:" << seqlen_qs[0]
              << "/" << seqlen_ks[0] << ", d:" << hdim_q << "/" << hdim_v << ", scale:" << scale
              << ", bias:" << bias << ", dbias:" << use_dbias << ", p_drop:" << p_drop
              << ", s_randval:" << s_randval << ", deterministic:" << deterministic
              << (deterministic ? std::string(", workspace:") +
                                      std::to_string(workspace_size_in_megabytes) + "MiB"
                                : "")
              << ", mask:" << mask << std::flush;

    auto fmha_traits = fmha_bwd_traits{hdim_q,
                                       hdim_v,
                                       data_type,
                                       mode == mode_enum::group,
                                       mask.type,
                                       bias.type,
                                       use_dbias,
                                       p_drop > 0.0f,
                                       s_randval,
                                       deterministic};
    auto fmha_args   = [&]() {
        /// NOTE: we broadcast bias from [1, 1, seqlen_q, seqlen_k] to [batch, nhead, seqlen_q,
        ///       seqlen_k] in this example, hence both the 'batch_stride_bias' &
        ///       'nhead_stride_bias' are 0.
        // setup stride_* arguments
        const ck_tile::index_t stride_q       = (i_perm ? hdim_q : nhead * hdim_q);
        const ck_tile::index_t stride_k       = (i_perm ? hdim_q : nhead_k * hdim_q);
        const ck_tile::index_t stride_v       = (i_perm ? hdim_v : nhead_k * hdim_v);
        const ck_tile::index_t stride_bias    = (max_seqlen_k);
        const ck_tile::index_t stride_o       = (o_perm ? hdim_v : nhead * hdim_v);
        const ck_tile::index_t stride_randval = (max_seqlen_k);
        const ck_tile::index_t stride_do      = (o_perm ? hdim_v : nhead * hdim_v);
        const ck_tile::index_t stride_dk      = (i_perm ? hdim_q : nhead * hdim_q);
        const ck_tile::index_t stride_dv      = (i_perm ? hdim_v : nhead * hdim_v);
        const ck_tile::index_t stride_dbias   = (i_perm ? max_seqlen_k : nhead * max_seqlen_k);
        // setup nhead_stride_* arguments
        const ck_tile::index_t nhead_stride_q       = (i_perm ? shape_seqlen_q * hdim_q : hdim_q);
        const ck_tile::index_t nhead_stride_k       = (i_perm ? shape_seqlen_k * hdim_q : hdim_q);
        const ck_tile::index_t nhead_stride_v       = (i_perm ? shape_seqlen_k * hdim_v : hdim_v);
        const ck_tile::index_t nhead_stride_bias    = 0;
        const ck_tile::index_t nhead_stride_o       = (o_perm ? shape_seqlen_q * hdim_v : hdim_v);
        const ck_tile::index_t nhead_stride_randval = (shape_seqlen_q * max_seqlen_k);
        const ck_tile::index_t nhead_stride_do      = (o_perm ? shape_seqlen_q * hdim_v : hdim_v);
        const ck_tile::index_t nhead_stride_lsed    = shape_seqlen_q;
        const ck_tile::index_t nhead_stride_dbias =
            (i_perm ? shape_seqlen_q * max_seqlen_k : max_seqlen_k);
        // setup batch_stride_* arguments
        const ck_tile::index_t batch_stride_q       = (nhead * shape_seqlen_q * hdim_q);
        const ck_tile::index_t batch_stride_k       = (nhead_k * shape_seqlen_k * hdim_q);
        const ck_tile::index_t batch_stride_v       = (nhead_k * shape_seqlen_k * hdim_v);
        const ck_tile::index_t batch_stride_bias    = 0;
        const ck_tile::index_t batch_stride_o       = (nhead * shape_seqlen_q * hdim_v);
        const ck_tile::index_t batch_stride_randval = (nhead * shape_seqlen_q * max_seqlen_k);
        const ck_tile::index_t batch_stride_do      = (nhead * shape_seqlen_q * hdim_v);
        const ck_tile::index_t batch_stride_lsed    = (nhead * shape_seqlen_q);
        const ck_tile::index_t batch_stride_dk      = (nhead * shape_seqlen_k * hdim_q);
        const ck_tile::index_t batch_stride_dv      = (nhead * shape_seqlen_k * hdim_v);
        const ck_tile::index_t batch_stride_dbias   = (nhead * shape_seqlen_q * max_seqlen_k);
        const ck_tile::index_t split_stride_dq_acc =
            (shape_batch * nhead * shape_seqlen_q * hdim_q);

        const auto drop_seed_offset = [&]() -> decltype(fmha_bwd_args::drop_seed_offset) {
            if(drop_prefs)
            {
                return std::make_pair(drop_seed_buf.GetDeviceBuffer(),
                                      drop_offset_buf.GetDeviceBuffer());
            }
            else
            {
                return std::make_pair(drop_seed, drop_offset);
            }
        }();

        const void* seqlen_q_ptr_dev = use_qpadding ? seqlen_q_dev.GetDeviceBuffer() : nullptr;
        const void* seqlen_k_ptr_dev = use_kpadding ? seqlen_k_dev.GetDeviceBuffer() : nullptr;

        return fmha_bwd_args{q_buf.GetDeviceBuffer(),
                             k_buf.GetDeviceBuffer(),
                             v_buf.GetDeviceBuffer(),
                             bias.type == bias_enum::alibi ? alibi_slope_buf.GetDeviceBuffer()
                                                             : bias_buf.GetDeviceBuffer(),
                             o_buf.GetDeviceBuffer(),
                             lse_buf.GetDeviceBuffer(),
                             do_buf.GetDeviceBuffer(),
                             d_buf.GetDeviceBuffer(),
                             randval_buf.GetDeviceBuffer(),
                             dq_buf.GetDeviceBuffer(),
                             dk_buf.GetDeviceBuffer(),
                             dv_buf.GetDeviceBuffer(),
                             dbias_buf.GetDeviceBuffer(),
                             dq_acc_buf.GetDeviceBuffer(),
                             seqstart_q.GetDeviceBuffer(),
                             seqstart_k.GetDeviceBuffer(),
                             seqlen_q_ptr_dev,
                             seqlen_k_ptr_dev,
                             nullptr,
                             nullptr,
                             shape_seqlen_q,
                             shape_seqlen_k,
                             batch,
                             max_seqlen_q,
                             max_seqlen_k,
                             hdim_q,
                             hdim_v,
                             nhead,
                             nhead_k,
                             scale,
                             stride_q,
                             stride_k,
                             stride_v,
                             bias.type == bias_enum::alibi ? (bias.rank_info == 0 ? 0 : nhead)
                                                             : stride_bias,
                             stride_o,
                             stride_randval,
                             stride_do,
                             stride_q, // stride_dq_acc
                             stride_q, // stride_dq
                             stride_dk,
                             stride_dv,
                             stride_dbias,
                             nhead_stride_q,
                             nhead_stride_k,
                             nhead_stride_v,
                             nhead_stride_bias,
                             nhead_stride_o,
                             nhead_stride_randval,
                             nhead_stride_do,
                             nhead_stride_lsed,
                             nhead_stride_q, // nhead_stride_dq_acc
                             nhead_stride_q, // nhead_stride_dq
                             nhead_stride_k, // nhead_stride_dk
                             nhead_stride_v, // nhead_stride_dv
                             nhead_stride_dbias,
                             batch_stride_q,
                             batch_stride_k,
                             batch_stride_v,
                             batch_stride_bias,
                             batch_stride_o,
                             batch_stride_randval,
                             batch_stride_do,
                             batch_stride_lsed,
                             batch_stride_q, // batch_stride_dq_acc
                             batch_stride_q, // batch_stride_dq
                             batch_stride_dk,
                             batch_stride_dv,
                             batch_stride_dbias,
                             split_stride_dq_acc,
                             mask.left,
                             mask.right,
                             static_cast<ck_tile::index_t>(mask.type),
                             p_drop,
                             p_undrop,
                             drop_seed_offset};
    }();

    const float ave_time = fmha_bwd(fmha_traits, fmha_args, stream_config);
    if(ave_time < 0)
    {
        std::cout << ", not supported yet" << std::flush << std::endl;
        return bwd_result::no_instance;
    }

    const float tflops     = static_cast<float>(flop) / 1.E9 / ave_time;
    const float gb_per_sec = num_byte / 1.E6 / ave_time;
    if(stream_config.time_kernel_)
    {
        std::cout << std::fixed << ", " << std::setprecision(3) << ave_time << " ms, "
                  << std::setprecision(2) << tflops << " TFlops, " << std::setprecision(2)
                  << gb_per_sec << " GB/s" << std::flush;
    }

    bool pass = true;
    if(!do_validation)
    {
        std::cout << std::flush << std::endl;
    }
    else
    {
        std::vector<ck_tile::HostTensor<QDataType>> q_host_refs;
        std::vector<ck_tile::HostTensor<KDataType>> k_host_refs;
        std::vector<ck_tile::HostTensor<VDataType>> v_host_refs;
        std::vector<ck_tile::HostTensor<ODataType>> o_host_refs;
        std::vector<ck_tile::HostTensor<RandValOutputDataType>> randval_host_refs;
        std::vector<ck_tile::HostTensor<AccDataType>> p_hp_host_refs;
        std::vector<ck_tile::HostTensor<GemmDataType>> p_lp_host_refs;

        randval_buf.FromDevice(randval_host.data());

        for(ck_tile::index_t wb = 0; wb < batch; ++wb)
        {
            // When padding is enabled, use logical lengths instead of computing from padded
            // prefix-sum
            const ck_tile::index_t real_seqlen_q =
                use_qpadding ? seqlen_qs[wb] : (seqstart_q_host[wb + 1] - seqstart_q_host[wb]);
            const ck_tile::index_t real_seqlen_k =
                use_kpadding ? seqlen_ks[wb] : (seqstart_k_host[wb + 1] - seqstart_k_host[wb]);

            // Skip forward reference computation for batches with zero length sequences
            if(real_seqlen_q == 0 || real_seqlen_k == 0)
            {
                continue;
            }

            // adjust matrix index according to the mode
            const ck_tile::index_t b = (mode == mode_enum::batch ? wb : 0);
            const ck_tile::index_t query_offset =
                (mode == mode_enum::batch ? 0 : seqstart_q_host[wb]);
            const ck_tile::index_t key_offset =
                (mode == mode_enum::batch ? 0 : seqstart_k_host[wb]);

            ck_tile::HostTensor<QDataType> q_host_ref({nhead, real_seqlen_q, hdim_q}); // q_g_m_k
            ck_tile::HostTensor<KDataType> k_host_ref({nhead, real_seqlen_k, hdim_q}); // k_g_n_k
            ck_tile::HostTensor<VDataType> v_host_ref({nhead, hdim_v, real_seqlen_k}); // v_g_o_n
            ck_tile::HostTensor<ODataType> o_host_ref({nhead, real_seqlen_q, hdim_v}); // o_g_m_o
            ck_tile::HostTensor<LSEDataType> lse_host_ref({nhead, real_seqlen_q});     // lse_g_m
            ck_tile::HostTensor<RandValOutputDataType> randval_host_ref(
                {nhead, real_seqlen_q, real_seqlen_k}); // randval_g_m_n
            ck_tile::HostTensor<AccDataType> s_host_ref(
                {nhead, real_seqlen_q, real_seqlen_k}); // s_g_m_n
            ck_tile::HostTensor<AccDataType> p_hp_host_ref(
                {nhead, real_seqlen_q, real_seqlen_k}); // p_hp_g_m_n high precision
            ck_tile::HostTensor<AccDataType> p_dropped_hp_host_ref(
                {nhead, real_seqlen_q, real_seqlen_k}); // p_dropped_hp_g_m_n high precision
            ck_tile::HostTensor<GemmDataType> p_lp_host_ref(
                {nhead, real_seqlen_q, real_seqlen_k}); // p_lp_g_m_n low precision

            ck_tile::index_t nr = nhead / nhead_k;

            // clang-format off
            // permute
            if(i_perm) q_host_ref.ForEach([&](auto& self, auto i) { self(i) = q_host(b, i[0], i[1] + query_offset, i[2]); });
            else       q_host_ref.ForEach([&](auto& self, auto i) { self(i) = q_host(b, i[1] + query_offset, i[0], i[2]); });

            if(i_perm) k_host_ref.ForEach([&](auto& self, auto i) { self(i) = k_host(b, i[0] / nr, i[1] + key_offset, i[2]); });
            else       k_host_ref.ForEach([&](auto& self, auto i) { self(i) = k_host(b, i[1] + key_offset, i[0] / nr, i[2]); });

            // v_host_ref: [nhead, hdim, seq], v_host: [b, h_k, s, d]
            if(i_perm) v_host_ref.ForEach([&](auto& self, auto i) { self(i) = v_host(b, i[0] / nr, i[2] + key_offset, i[1]); });
            // v_host_ref: [nhead, hdim, seq], v_host: [b, s, h_k, d]
            else       v_host_ref.ForEach([&](auto& self, auto i) { self(i) = v_host(b, i[2] + key_offset, i[0] / nr, i[1]); });
            // clang-format on

            // reference
            // S = scale * Q * K^T
            ck_tile::reference_batched_gemm<QDataType, KDataType, AccDataType, AccDataType>(
                q_host_ref,
                k_host_ref,
                s_host_ref,
                ck_tile::identity{},
                ck_tile::identity{},
                ck_tile::scales(scale)); // s_g_m_n = scale * q_g_m_k@k_g_n_k

            if(bias.type == bias_enum::elementwise_bias)
            {
                // elementwise bias
                ck_tile::HostTensor<BiasDataType> bias_host_ref({1, real_seqlen_q, real_seqlen_k});
                // clang-format off
                if(i_perm)
                    bias_host_ref.ForEach([&](auto& self, auto i) { self(i) = bias_host(0, 0, i[1] + query_offset, i[2]); });
                else
                    bias_host_ref.ForEach([&](auto& self, auto i) { self(i) = bias_host(0, i[1] + query_offset, 0, i[2]); });
                // clang-format on

                // broadcast from [1, real_seqlen_q, real_seqlen_k] to [nhead, real_seqlen_q,
                // real_seqlen_k]
                ck_tile::reference_batched_elementwise<AccDataType,
                                                       BiasDataType,
                                                       AccDataType,
                                                       AccDataType>(
                    s_host_ref, bias_host_ref, s_host_ref);
            }
            else if(bias.type == bias_enum::alibi)
            {
                // alibi construct elementwise bias to verify
                auto alibi_host = [&]() {
                    if(mask.type != mask_enum::no_mask)
                    {
                        return ck_tile::make_alibi_from_lr_mask<AccDataType, false>(
                            0,
                            mask.left,
                            mask.right,
                            real_seqlen_q,
                            real_seqlen_k,
                            static_cast<ck_tile::GenericAttentionMaskEnum>(mask.type));
                    }
                    else
                    {
                        return ck_tile::Alibi<AccDataType, false>{
                            0, real_seqlen_q, real_seqlen_k, ck_tile::AlibiMode::FROM_BOTTOM_RIGHT};
                    }
                }();

                ck_tile::HostTensor<AccDataType> alibi_bias_host_ref(
                    {nhead, real_seqlen_q, real_seqlen_k});
                auto i_b_slope = bias.rank_info == 0 ? 0 : wb;
                for(auto i_h = 0; i_h < nhead; i_h++)
                {
                    AccDataType current_slope = alibi_slope_host(i_b_slope, i_h);
                    alibi_host.slope          = alibi_host.mode == ck_tile::AlibiMode::VERTICAL
                                                    ? current_slope
                                                    : -current_slope;
                    for(auto i_r = 0; i_r < real_seqlen_q; i_r++)
                    {
                        for(auto i_c = 0; i_c < real_seqlen_k; i_c++)
                        {
                            AccDataType pixel = 0;
                            alibi_host.update(pixel, i_r, i_c);
                            alibi_bias_host_ref(i_h, i_r, i_c) = pixel;
                        }
                    }
                }
                // [nhead, real_seqlen_q, real_seqlen_k]
                ck_tile::reference_batched_elementwise<AccDataType,
                                                       AccDataType,
                                                       AccDataType,
                                                       AccDataType>(
                    s_host_ref, alibi_bias_host_ref, s_host_ref);
            }

            if(mask.type == mask_enum::no_mask)
            {
                ck_tile::reference_batched_masking<AccDataType>(
                    s_host_ref, FmhaMasks::NoMask{real_seqlen_q, real_seqlen_k});
            }
            else if(mask.type == mask_enum::window_generic)
            {
                ck_tile::reference_batched_masking<AccDataType>(
                    s_host_ref,
                    ck_tile::make_generic_attention_mask_from_lr_window<FmhaMasks::GenericMask>(
                        mask.left, mask.right, real_seqlen_q, real_seqlen_k));
            }
            else
            {
                // if left window size is negative, means causal
                // else means generic (for current batch)
                if(mask.left < 0)
                    ck_tile::reference_batched_masking<AccDataType>(
                        s_host_ref,
                        ck_tile::make_generic_attention_mask_from_lr_window<FmhaMasks::CausalMask>(
                            mask.left,
                            mask.right,
                            real_seqlen_q,
                            real_seqlen_k,
                            mask.type == mask_enum::mask_top_left));
                else
                    ck_tile::reference_batched_masking<AccDataType>(
                        s_host_ref,
                        ck_tile::make_generic_attention_mask_from_lr_window<FmhaMasks::GenericMask>(
                            mask.left,
                            mask.right,
                            real_seqlen_q,
                            real_seqlen_k,
                            mask.type == mask_enum::mask_top_left));
            }
            const ck_tile::HostTensor<AccDataType> masked_s_host_ref = s_host_ref;
            ck_tile::reference_batched_softmax<AccDataType, LSEDataType, AccDataType>(
                s_host_ref, p_hp_host_ref, ck_tile::identity{}, lse_host_ref);

            if(p_drop > 0)
            {
                p_dropped_hp_host_ref = p_hp_host_ref;
                ck_tile::reference_batched_dropout_randval(
                    randval_host_ref, wb, drop_seed, drop_offset);
                ck_tile::reference_batched_dropout(
                    p_dropped_hp_host_ref, randval_host_ref, p_undrop_in_uint8_t, rp_undrop);
                p_lp_host_ref = p_dropped_hp_host_ref.template CopyAsType<GemmDataType>();

                ck_tile::HostTensor<RandValOutputDataType> randval_host_result(
                    {nhead, real_seqlen_q, real_seqlen_k});
                randval_host_result.ForEach([&](auto& self, const auto& idx) {
                    self(idx) = randval_host(b, idx[0], idx[1] + query_offset, idx[2]);
                });
                masked_s_host_ref.ForEach([&](const auto& self, const auto& idx) {
                    // Ignore all masked values in validation check
                    if(std::isinf(self(idx)))
                    {
                        randval_host_ref(idx)    = 0;
                        randval_host_result(idx) = 0;
                    }
                });
                bool cur_pass = ck_tile::check_err(randval_host_result,
                                                   randval_host_ref,
                                                   "DROPOUT RANDVAL Error: Incorrect results!");
                pass &= cur_pass;
                if(!cur_pass)
                {
                    break;
                }
            }
            else
            {
                p_lp_host_ref = p_hp_host_ref.template CopyAsType<GemmDataType>();
            }

            // O = P * V
            ck_tile::reference_batched_gemm<GemmDataType, VDataType, AccDataType, ODataType>(
                p_lp_host_ref, v_host_ref, o_host_ref); // o_g_m_o = p_lp_g_m_n@v_g_o_n

            // clang-format off
            // permute
            if(o_perm) o_host_ref.ForEach([&](auto& self, auto idx) { o_host(b, idx[0], idx[1] + query_offset, idx[2]) = self(idx); });
            else       o_host_ref.ForEach([&](auto& self, auto idx) { o_host(b, idx[1] + query_offset, idx[0], idx[2]) = self(idx); });

            lse_host_ref.ForEach([&](auto& self, auto idx) { lse_host(b, idx[0], idx[1] + query_offset) = self(idx); });
            // clang-format on

            q_host_refs.push_back(q_host_ref);
            k_host_refs.push_back(k_host_ref);
            v_host_refs.push_back(v_host_ref);
            o_host_refs.push_back(o_host_ref);
            p_hp_host_refs.push_back(p_hp_host_ref);
            p_lp_host_refs.push_back(p_lp_host_ref);
            if(p_drop > 0)
            {
                randval_host_refs.push_back(randval_host_ref);
            }
        }

        // set to bad values to check if the kernel writes to these buffers
        ck_tile::FillConstant<QGradDataType>{ck_tile::numeric<QGradDataType>::infinity()}(dq_host);
        ck_tile::FillConstant<KGradDataType>{ck_tile::numeric<KGradDataType>::infinity()}(dk_host);
        ck_tile::FillConstant<VGradDataType>{ck_tile::numeric<VGradDataType>::infinity()}(dv_host);
        ck_tile::FillConstant<AccDataType>{ck_tile::numeric<AccDataType>::infinity()}(dq_acc_host);
        dq_buf.ToDevice(dq_host.data());
        dk_buf.ToDevice(dk_host.data());
        dv_buf.ToDevice(dv_host.data());
        dq_acc_buf.ToDevice(dq_acc_host.data());

        o_buf.ToDevice(o_host.data());
        lse_buf.ToDevice(lse_host.data());
        dbias_buf.SetZero();

        // non-deterministic kernels use atomic add to write dq
        // Some block may be skipped with causal mask and dq are not set to zeros
        // In these cases thus we need to zero out it first
        if(!deterministic || mask.type != mask_enum::no_mask)
            dq_acc_buf.SetZero();

        ck_tile::stream_config stream_config_v{nullptr, true, 0, 0, 1};
        fmha_bwd(fmha_traits, fmha_args, stream_config_v);

        dq_buf.FromDevice(dq_host.data());
        dk_buf.FromDevice(dk_host.data());
        dv_buf.FromDevice(dv_host.data());
        dbias_buf.FromDevice(dbias_host.data());

        // Track the index into reference vectors (may differ from wb if batches were skipped)
        ck_tile::index_t ref_idx = 0;

        for(ck_tile::index_t wb = 0; wb < batch; ++wb)
        {
            // When padding is enabled, use logical lengths instead of computing from padded
            // prefix-sum
            const ck_tile::index_t real_seqlen_q =
                use_qpadding ? seqlen_qs[wb] : (seqstart_q_host[wb + 1] - seqstart_q_host[wb]);
            const ck_tile::index_t real_seqlen_k =
                use_kpadding ? seqlen_ks[wb] : (seqstart_k_host[wb + 1] - seqstart_k_host[wb]);

            // Skip validation for batches with zero length sequences
            if(real_seqlen_q == 0 || real_seqlen_k == 0)
            {
                continue;
            }

            // adjust matrix index according to the mode
            const ck_tile::index_t b = (mode == mode_enum::batch ? wb : 0);
            const ck_tile::index_t query_offset =
                (mode == mode_enum::batch ? 0 : seqstart_q_host[wb]);
            const ck_tile::index_t key_offset =
                (mode == mode_enum::batch ? 0 : seqstart_k_host[wb]);

            ck_tile::HostTensor<OGradDataType> do_host_ref(
                {nhead, real_seqlen_q, hdim_v}); // do_g_m_o
            ck_tile::HostTensor<AccDataType> ds_hp_host_ref(
                {nhead, real_seqlen_q, real_seqlen_k}); // ds_g_m_n high precision
            ck_tile::HostTensor<GemmDataType> ds_lp_host_ref(
                {nhead, real_seqlen_q, real_seqlen_k}); // ds_g_m_n low precision
            ck_tile::HostTensor<AccDataType> dp_hp_host_ref(
                {nhead, real_seqlen_q, real_seqlen_k}); // dp_g_m_n high precision
            ck_tile::HostTensor<BiasGradDataType> dbias_host_ref(
                {nhead, real_seqlen_q, real_seqlen_k}); // dbias_g_m_n
            ck_tile::HostTensor<QGradDataType> dq_host_ref(
                {nhead, real_seqlen_q, hdim_q}); // dq_g_m_k
            ck_tile::HostTensor<KGradDataType> dk_host_ref(
                {nhead, real_seqlen_k, hdim_q}); // dk_g_n_k
            ck_tile::HostTensor<VGradDataType> dv_host_ref(
                {nhead, real_seqlen_k, hdim_v}); // dv_g_n_o

            // clang-format off
            if(o_perm) do_host_ref.ForEach([&](auto& self, auto i) { self(i) = do_host(b, i[0], i[1] + query_offset, i[2]); });
            else       do_host_ref.ForEach([&](auto& self, auto i) { self(i) = do_host(b, i[1] + query_offset, i[0], i[2]); });
            // clang-format on

            // dP = dO@V x Z w/  dropout
            // dP = dO@V     w/o dropout
            auto v_t_host_ref = v_host_refs[ref_idx].transpose({0, 2, 1}); // v_g_o_n -> v_g_n_o
            ck_tile::reference_batched_gemm<OGradDataType, VDataType, AccDataType, AccDataType>(
                do_host_ref, v_t_host_ref, dp_hp_host_ref); // dp_g_m_n = do_g_m_o@v_g_n_o

            if(p_drop > 0)
            {
                ck_tile::reference_batched_dropout(
                    dp_hp_host_ref, randval_host_refs[ref_idx], p_undrop_in_uint8_t, rp_undrop);
            }

            // dS_i_j = P_i_j .* (dP_i_j - dO_i dot O_i)
            ck_tile::make_ParallelTensorFunctor(
                [&](auto i0, auto i1, auto i2) {
                    AccDataType do_dot_o = 0;
                    for(int o = 0; o < hdim_v; o++)
                    {
                        do_dot_o +=
                            ck_tile::type_convert<AccDataType>(do_host_ref(i0, i1, o)) *
                            ck_tile::type_convert<AccDataType>(o_host_refs[ref_idx](i0, i1, o));
                    }
                    ds_hp_host_ref(i0, i1, i2) =
                        ck_tile::type_convert<AccDataType>(p_hp_host_refs[ref_idx](i0, i1, i2) *
                                                           (dp_hp_host_ref(i0, i1, i2) - do_dot_o));
                },
                ds_hp_host_ref.mDesc.get_lengths()[0],
                ds_hp_host_ref.mDesc.get_lengths()[1],
                ds_hp_host_ref.mDesc.get_lengths()[2])(std::thread::hardware_concurrency());

            if(use_dbias)
            {
                dbias_host_ref = ds_hp_host_ref.template CopyAsType<BiasGradDataType>();
            }

            ds_lp_host_ref = ds_hp_host_ref.template CopyAsType<GemmDataType>();

            // dV = P_drop^T@dO^T
            // dV = P^T@dO^T w/o dropout
            auto p_t_lp_host_ref =
                p_lp_host_refs[ref_idx].transpose({0, 2, 1});      // p_lp_g_m_n -> p_lp_g_n_m
            auto do_t_host_ref = do_host_ref.transpose({0, 2, 1}); // do_g_m_o -> do_g_o_m
            ck_tile::
                reference_batched_gemm<GemmDataType, OGradDataType, AccDataType, VGradDataType>(
                    p_t_lp_host_ref, do_t_host_ref, dv_host_ref); // dv_g_n_o = p_lp_g_n_m@do_g_o_m

            // dQ = scale * dS@K^T
            auto k_t_host_ref = k_host_refs[ref_idx].transpose({0, 2, 1}); // k_g_n_k -> k_g_k_n
            ck_tile::reference_batched_gemm<GemmDataType, KDataType, AccDataType, QGradDataType>(
                ds_lp_host_ref,
                k_t_host_ref,
                dq_host_ref,
                ck_tile::identity{},
                ck_tile::identity{},
                ck_tile::scales(scale)); // dq_g_m_k = ds_g_m_n@k_g_k_n

            // dK = scale * dS^T@Q^T
            auto ds_t_lp_host_ref = ds_lp_host_ref.transpose({0, 2, 1}); // ds_g_m_n -> ds_g_n_m
            auto q_t_host_ref     = q_host_refs[ref_idx].transpose({0, 2, 1}); // q_g_m_k -> q_g_k_m
            ck_tile::reference_batched_gemm<GemmDataType, QDataType, AccDataType, KGradDataType>(
                ds_t_lp_host_ref,
                q_t_host_ref,
                dk_host_ref,
                ck_tile::identity{},
                ck_tile::identity{},
                ck_tile::scales(scale)); // dk_g_n_k = ds_g_n_m@q_g_k_m

            ck_tile::HostTensor<QGradDataType> dq_host_result(
                {nhead, real_seqlen_q, hdim_q}); // dq_g_m_k
            ck_tile::HostTensor<KGradDataType> dk_host_result(
                {nhead, real_seqlen_k, hdim_q}); // dk_g_n_k
            ck_tile::HostTensor<VGradDataType> dv_host_result(
                {nhead, real_seqlen_k, hdim_v}); // dv_g_n_o
            ck_tile::HostTensor<BiasGradDataType> dbias_host_result(
                {nhead, real_seqlen_q, real_seqlen_k}); // dbias_g_m_n

            // clang-format off
            // permute
            if(i_perm) dq_host_result.ForEach([&](auto& self, auto idx) {self(idx) = dq_host(b, idx[0], idx[1] + query_offset, idx[2]); });
            else       dq_host_result.ForEach([&](auto& self, auto idx) {self(idx) = dq_host(b, idx[1] + query_offset, idx[0], idx[2]); });

            if(i_perm) dk_host_result.ForEach([&](auto& self, auto idx) {self(idx) = dk_host(b, idx[0], idx[1] + key_offset, idx[2]); });
            else       dk_host_result.ForEach([&](auto& self, auto idx) {self(idx) = dk_host(b, idx[1] + key_offset, idx[0], idx[2]); });

            if(i_perm) dv_host_result.ForEach([&](auto& self, auto idx) {self(idx) = dv_host(b, idx[0], idx[1] + key_offset, idx[2]); });
            else       dv_host_result.ForEach([&](auto& self, auto idx) {self(idx) = dv_host(b, idx[1] + key_offset, idx[0], idx[2]); });

            if(use_dbias)
            {
                if(i_perm) dbias_host_result.ForEach([&](auto& self, auto idx) {self(idx) = dbias_host(b, idx[0], idx[1] + query_offset, idx[2]); });
                else       dbias_host_result.ForEach([&](auto& self, auto idx) {self(idx) = dbias_host(b, idx[1] + query_offset, idx[0], idx[2]); });
            }
            // clang-format on

            auto [rtol, atol] = get_elimit<DataTypeConfig>(hdim_q, hdim_v);
            bool dq_cur_pass  = ck_tile::check_err(dq_host_result,
                                                  dq_host_ref,
                                                  std::string("Error: QGrad Incorrect results!"),
                                                  rtol,
                                                  atol);
            bool dk_cur_pass  = ck_tile::check_err(dk_host_result,
                                                  dk_host_ref,
                                                  std::string("Error: KGrad Incorrect results!"),
                                                  rtol,
                                                  atol);
            bool dv_cur_pass  = ck_tile::check_err(dv_host_result,
                                                  dv_host_ref,
                                                  std::string("Error: VGrad Incorrect results!"),
                                                  rtol,
                                                  atol);

            bool dbias_cur_pass = true;
            if(use_dbias)
            {
                dbias_cur_pass =
                    ck_tile::check_err(dbias_host_result,
                                       dbias_host_ref,
                                       std::string("Error: BiasGrad Incorrect results!"),
                                       rtol,
                                       atol);
            }
            pass &= (dq_cur_pass & dk_cur_pass & dv_cur_pass & dbias_cur_pass);
            if(!(dq_cur_pass & dk_cur_pass & dv_cur_pass & dbias_cur_pass))
            {
                std::cerr << "mismatch found at batch: " << wb << std::endl
                          << "\tseqlen_q: " << real_seqlen_q << std::endl
                          << "\tseqlen_k: " << real_seqlen_k << std::endl
                          << "\tseqstart_q: " << seqstart_q_host << std::endl
                          << "\tseqstart_k: " << seqstart_k_host << std::endl;

                break;
            }

            // Increment reference vector index for successfully validated batches
            ref_idx++;
        }

        std::cout << ", valid:" << (pass ? "y" : "n") << std::flush << std::endl;
    }

    if(json)
    {
        dump_fmha_bwd_json_results(
            *json,
            data_type,
            mode == mode_enum::batch ? "batch" : "group",
            i_perm ? "true" : "false",
            o_perm ? "true" : "false",
            batch,
            nhead,
            nhead_k,
            seqlen_qs[0],
            seqlen_ks[0],
            hdim_q,
            hdim_v,
            scale,
            bias.type == bias_enum::elementwise_bias
                ? "elementwise_bias"
                : (bias.type == bias_enum::alibi ? "alibi" : "no_bias"),
            use_dbias ? "true" : "false",
            p_drop,
            s_randval,
            deterministic,
            mask.type == mask_enum::no_mask
                ? "no_mask"
                : (mask.type == mask_enum::window_generic
                       ? "window_generic"
                       : (mask.type == mask_enum::mask_top_left
                              ? "mask_top_left"
                              : (mask.type == mask_enum::mask_bottom_right ? "mask_bottom_right"
                                                                           : "mask_generic"))),
            mask.left,
            mask.right,
            workspace_size_in_megabytes,
            pass,
            ave_time,
            tflops,
            gb_per_sec);
    }

    return pass ? bwd_result::success : bwd_result::failure;
}
